Interactions of fusidic acid and elongation factor G with lipid membranes

Albumin as a functional carrier solubilizing and facilitating fusidic acid transmembrane delivery into Gram-negative bacteria

Reversing the bacterial resistance is of great significance and importance. Fusidic acid (FA) is commonly effective against Gram-positive bacterial infections, but most Gram-negative bacteria have intrinsic resistance to FA, primarily due to the strong cell membrane-FA interactions, which highly inhibit the intracellular transport of FA. Herein, we use albumin (bovine serum albumin, BSA) as a bifunctional carrier to solubilize FA and facilitate its transmembrane delivery into Gram-negative bacterial cells. The water solubility of FA is significantly enhanced from 11.87 to 442.20 μg/mL by 5 mg/mL BSA after forming FA-BSA complex. Furthermore, FA-BSA (200 μg/mL) causes 99.96 % viability loss to the model pathogen E. coli upon incubation for 3 h, while free FA or BSA alone shows little activity. Elongation of E. coli cells after treated by FA-BSA is demonstrated by SEM, and the transmembrane transport of FA-BSA is demonstrated by CLSM. Interestingly, increasing the BSA amount substantially reduce the antibacterial activity of FA-BSA, implying an albumin-based transmembrane delivery mechanism may exist. This is the first report regarding successfully reversing the intrinsic resistance of Gram-negative bacteria to FA in the form of FA-BSA. The ready availability of albumin and the simple preparation allows FA-BSA to have great potentials for clinical use.

Effect of Fusidic Acid and Some Nitrogen-Containing Derivatives on Liposomal and Mitochondrial Membranes

The paper assesses the membranotropic action of the natural antibiotic fusidic acid (FA) and its derivatives. It was found that a FA analogue with ethylenediamine moiety (derivative 2), in contrast to native FA and 3,11-dioxime analogue (derivative 1), is able to increase the mobility of the lipid bilayer in the zone of lipid headgroups, as well as to induce permeabilization of lecithin liposome membranes. A similar effect of derivative 2 is also observed in the case of rat liver mitochondrial membranes. We noted a decrease in the microviscosity of the mitochondrial membrane and nonspecific permeabilization of organelle membranes in the presence of this agent, which was accompanied by a decrease in mitochondrial Δψ and OXPHOS efficiency. This led to a reduction in mitochondrial calcium retention capacity. The derivatives also reduced the production of H2O2 by mitochondria. The paper considers the relationship between the structure of the tested compounds and the observed effects.

Prediction of Streptococcus uberis clinical mastitis treatment success in dairy herds by means of mass spectrometry and machine-learning

Streptococcus uberis is one of the leading pathogens causing mastitis worldwide. Identification of S. uberis strains that fail to respond to treatment with antibiotics is essential for better decision making and treatment selection. We demonstrate that the combination of supervised machine learning and matrix-assisted laser desorption ionization/time of flight (MALDI-TOF) mass spectrometry can discriminate strains of S. uberis causing clinical mastitis that are likely to be responsive or unresponsive to treatment. Diagnostics prediction systems trained on 90 individuals from 26 different farms achieved up to 86.2% and 71.5% in terms of accuracy and Cohen’s kappa. The performance was further increased by adding metadata (parity, somatic cell count of previous lactation and count of positive mastitis cases) to encoded MALDI-TOF spectra, which increased accuracy and Cohen’s kappa to 92.2% and 84.1% respectively. A computational framework integrating protein–protein networks and structural protein information to the machine learning results unveiled the molecular determinants underlying the responsive and unresponsive phenotypes.

Multilayered polyelectrolyte microcapsules: interaction with the enzyme cytochrome C oxidase

Cell-sized polyelectrolyte capsules functionalized with a redox-driven proton pump protein were assembled for the first time. The interaction of polyelectrolyte microcapsules, fabricated by electrostatic layer-by-layer assembly, with cytochrome c oxidase molecules was investigated. We found that the cytochrome c oxidase retained its functionality, that the functionalized microcapsules interacting with cytochrome c oxidase were permeable and that the permeability characteristics of the microcapsule shell depend on the shell components. This work provides a significant input towards the fabrication of an integrated device made of biological components and based on specific biomolecular functions and properties.

Towards the immunoproteome of Neisseria meningitidis

Despite the introduction of conjugated polysaccharide vaccines for many of the Neisseria meningitidis serogroups, neisserial infections continue to cause septicaemia and meningitis across the world. This is in part due to the difficulties in developing a, cross-protective vaccine that is effective against all serogroups, including serogroup B meningococci. Although convalescent N. meningitidis patients develop a natural long-lasting cross-protective immunity, the antigens that mediate this response remain unknown. To help define the target of this protective immunity we identified the proteins recognized by IgG in sera from meningococcal patients by a combination of 2D protein gels, western blots and mass spectrometry. Although a number of outer membrane antigens were identified the majority of the antigens were cytoplasmic, with roles in cellular processes and metabolism. When recombinant proteins were expressed and used to raise sera in mice, none of the antigens elicited a positive SBA result, however flow cytometry did demonstrate that some, including the ribosomal protein, RplY were localised to the neisserial cell surface.